Bipolar SRAM having word lines as vertically stacked pairs of conductive lines parallelly formed with holding current lines

ABSTRACT

There is implemented memory cells and corresponding signal lines associated therewith in bipolar type static random access memories employing wirings of multi-layer construction for transmitting a common signal therethrough such as with respect to the individual word lines. The word lines implemented are formed from at least a pair of stacked conductive layers and which layers have interposed therebetween an insulating film. The pair of layers form a pair of wiring lines wherein together they form a work line and wherein the wiring lines are, furthermore, interconnected at predetermined intervals along the lengths thereof. This leads to the ability to decrease the chip size of semiconductor integrated circuits noting that a decrease in the voltage drop of a signal line results, and to prevent electromigration in the signal (wiring) lines. There is, furthermore, implemented a current line formed from a conductor layer which is extended along the direction of the word lines over a region, together with the word lines, where the memory cells are formed.

This is a division of application Ser. No. 07/160,259, filed Feb. 25, 1988 and now U.S. Pat. No. 4,926,378.

BACKGROUND OF THE INVENTION

1. Technical Field of the Invention

This invention relates to a semiconductor memory, and particularly to an effective technique to be applied to a formation of a memory cell and a signal line in bipolar static random access memories.

2. Description of the Prior Art

In previous bipolar static random access memories, the aluminum two-layer wiring technique was applied: in this case, the first aluminium layer formed the digit lines (or data lines) of the memory array, and the second layer formed the word lines and holding current lines that crossed with the digit lines at right angles (Japan Patent Application No. 60-169808 published as document No. 62-31154).

SUMMARY OF THE INVENTION

However, as the manufacturing dimensions of semiconductor devices are becoming smaller and smaller with the development of lithography, dimensioning of the memory array is apt to be determined with the requirements in implementing a layout arrangement of the aluminium wiring. That is, in static random access memories (RAM), a current flowing through the word line or current keeping line is determined by the access velocity and so on, but when the current is increased to attain a desired access velocity, wiring resistances of the word line, etc., will increase the potential drop, or the electromigration will be easy to occur. Therefore, even if an area occupied by a memory cell can be decreased with the decrease of the capacitor area when the technology of manufacturing a miniaturized element or the U-groove isolation is applied, or the electrode construction is improved, a wiring width of the word line etc. cannot be made too small; thus, a decrease of the dimension of memory arrays and therefore memory cells becomes difficult because the aluminum wiring cannot be too wide.

The tendency for further miniauthorization will be strong in the future because of memories having a large bit storage capacity.

When the memory bit storage capacity in semiconductor chips is increased, a long word-line, etc., will be needed for wiring, and the potential drop will be larger and larger, so it is feared that the operation margin of the memory cell would decrease, or the read-out velocity would be different between that of the first cell and the last one.

An object of the present invention is to decrease the chip size in large-scale semiconductor integrated circuits.

Another object of the invention is to decrease the potential drop resulting from the wirings in the large-scale semiconductor integrated circuit, and to prevent the electromigration.

The other objects and new characteristics of the invention will be clear with the descriptions of the specification and the attached drawings.

The following relates to improved aspects of the present invention: for example, wirings relating to the same signal are implemented by employing at least two layers on the semiconductor region where circuit elements are arranged in high density, and this is the case for a word line on the bipolar static RAM.

By using the above means, the wiring cross section can be decreased without narrowing the wiring width, and an area occupied by the circuit is not restricted by the width of aluminum wirings so that the above object is attained, that is, a chip size can be decreased in large-scale semiconductor integrated circuits.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an equivalent circuit of a static RAM consisting of emitter-coupled memory cells according to the first embodiment of the present invention.

FIG. 2 shows a layout of the emitter-coupled memory cells and signal lines according to the second embodiment of the invention.

FIG. 3 is a cross sectional view by line II--II of FIG. 2.

FIG. 4 is a cross sectional view by line III--III of FIG. 2.

FIG. 5 is a cross sectional view by line IV--IV of FIG. 2.

FIG. 6 shows a layout of signal lines of the static RAM according to the third embodiment of the invention.

FIG. 7 shows a layout of signal lines of the static RAM according to the fourth embodiment of the invention.

FIG. 8A, FIG. 8B and FIG. 8C illustrate the circuit and timing for explaining operations of the typical and conventional, bipolar static RAM.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Operation explanation of the typical, bipolar static RAM:

Before describing the embodiments of the present invention, the operation of a typical, bipolar static RAM circuit shall be explained referring to FIGS. 8A, 8B and 8C. The bipolar static RAM illustrated in FIG. 8A is formed on a semiconductor substrate by using known semiconductor integrated circuit technology. External terminals are provided in conjunction with signals associated with XA₀ to XA_(K), from YA₀ to YA_(l), D_(OUT), D_(IN), CS, WE, --V_(EE), and GND.

As for the memory cells, one of which MC1 is shown in terms of a specific circuit which includes a flip flop circuit arrangement; the circuit is constructed with npn driving transistors Q₃₂ and Q₃₃ having the base-collector cross connections for each other, and with pnp transistors Q₃₄ and Q₃₅ that are connected to each collector of the npn transistors and which are cross-connected to each other. The driving transistors Q₃₂ and Q₃₃ have no other restriction other than being of multi-emitter construction, and wherein each one of the emitters is commonly connected to the constant voltage source --V_(EE) that supplies hold current In. The other emitters of the above transistors Q₃₂ and Q₃₃ are connected respectively to a pair of data (digit) lines D₀ and D₀. And the commonly connected emitters of transistors Q₃₄ and Q₃₅ are connected to word line W₀.

In accordance with the above mentioned memory cell MC1, similar ones, for example 64 memories, are arranged in each of the rows and commonly connected to the same word line W₀ ; in FIG. 8A, one memory cell in the same row is shown as a black box. And in the vertical lines, similar memory cells for example, 64 in number are connected in common to a column of complementary data lines D₀ and D₀ ; in the figure, one cell in the same column is also shown as a black box. Such 64×64 memory cells are arranged as a matrix which forms a memory array M-ARY.

Representatives word lines such as W₀ and Wn shown in FIG. 8A can be selected by using word line driving transistors Q₂₈ and Q₂₈ that receive X address decoding signals X₀ and Xn. The signals are formed by an X address decoder.

An address signal supplied from a circuit device, not shown in the figure, is input to address buffer XAB₀ or XAB_(K) through address input terminal XA₀ or XA_(K). The address buffer XAB₀ or XAB_(K) forms a complementary signal including an inverting and a non-inverting address signal according to the input address signal and supplies it to the X address decoder. Therefore, a word line is selected in accordance with the binary state of the applied address signals at the inputs of address buffers XAB_(O) through XAB_(K).

A pair of complementary data lines D₀ and D₀ are connected to a constant current source I_(R) (which is used commonly for all data lines) through transistors Q₁₉ and Q₂₁ which are used for column switches. The current source I_(R) is constructed with transistors Q₂₅ and Q₂₇ having emitter resistances R_(E7) respectively, and R_(E5), and a constant voltage V_(B3) which is applied to the base of both transistors.

The bases of the transistors Q₁₉ and Q₂₁ are coupled to receive a decoded signal Y₀ that is formed by Y decoder.

An address signal supplied from the above mentioned circuit device not shown in the figure, is input to address buffer YAB₀ or YAB_(l) through address input terminal YA₀ or YA_(l) respectively. Each of the address buffers YAB₀ to YAB_(l) forms a complementary signal including an inverting and a non-inverting address signal and transmit it to the Y decoder in accordance with the Binary state of the input address signal at the inputs of address buffers YAB_(O) to YAB_(l). This selects a pair of data lines.

In this embodiment, the following circuit is used for providing a bias voltage to the data lines not being selected.

A serial connection of a diode D₉ and a resistor R₇ is connected between the base and the collector of a multi-emitter transistor Q₁₈, and in this case, the collector is grounded. The serial connection of the diode D₉ and the resistor R₇ also connected to the same, constant current source I_(R) through a similarly connected and biased transistor Q₂₀ as the above mentioned column switch transistors. The emitters of the transistor Q₁₈ are connected to a pair of data lines D₀ and D₀, respectively.

Therefore, the transistor Q₁₈ can be either as a multi-emitter transistor or as two transistors, the bases or the collectors of which are connected are in common, respectively.

The pair of the data lines have a constant minute-current source. That is, a minute current is always sunk into transistors Q₃₀ and Q₃₁ that commonly receive a constant voltage V_(B1) at the base thereof and which have emitter resistances R_(E9) and R_(E8). Thus, a potential of the non-selected data lines is biased with a voltage that is formed by summation of the forward voltage V_(F) of diode D₉ and the base-emitter voltage V_(BE) of the transistor Q₁₈.

The constant current source I_(R) has transistors Q₂₂, Q₂₃ and Q₂₄, each of which has the base supplied with a bias voltage V_(B2). The voltage V_(B2) is selected to be a little lower than the selection level of the Y address decoding signal.

Therefore, if a decoding signal Y₀ is less than the above voltage V_(B2) when, for example, the data lines are switched and from a selection from that of data lines D₀, D₀ to data lines D₁, D₁ by the switching action of the column switch, transistors from Q₁₉ to Q₂₁ are turned off and transistors Q₂₂ to Q₂₄ are turned on. This, at first, causes a current I_(R) flowing through the data lines D₀ and D₀ to be cut off, and nextly, the transistors from Q₂₂ to Q₂₄ to turn off when a decoding signal Y₁ becomes larger than the voltage V_(B2), wherein a column switch transistor (not shown in the figure) which is connected to the data lines D₁ and D₁ and is responsive to signal Y₁ is turned on.

In this way, the constant current I_(R) is prevented from flowing in both of the data lines with a current distributing ratio depending on the address decoding signal level.

For the purpose of writing into and reading from the memory cell, a pair of the data lines D₀ and D₀ have current switching transistors Q₁₂ and Q₁₃, the emitters of which are connected to the data lines.

A collector output signal of these transistors Q₁₂ and Q₁₃ is transmitted to an input of a sensing amplifier SA.

The sensing amplifier SA comprises the following circuit elements.

A constant current source I₄ is connected to each emitter of transistors Q₁₄ and Q₁₅, which receive a constant voltage --I₃ R₆ ; in this case the voltage is generated from a resistor R₆ wherein a constant current I₃ is flowing therethrough. Each collector associated with transistors Q₁₄ and Q₁₅ is connected to resistors R₄ and R₅, respectively.

Each collector of the transistors Q₁₂ and Q₁₃ is connected to the emitter of the transistors Q₁₄ and Q₁₅, respectively. The collector output of the transistors Q₁₄ and Q₁₅ is transmitted to the base of transistors Q₁₆ and Q₁₇, respectively, wherein the emitters of which are coupled to data output buffer (DOB) and via diodes D₄ and D₃, provided for level shifting, respectively, are coupled to a constant current source I₅ series connections between the emitters of transistors Q₁₆ and Q₁₇ and supply-V_(EE).

The constant currents I₃ and I₄, and the resistors from R₄ to R₆ are set in such a way that an output level through the diodes D₃ and D₄ will be the same as the input level of a data output buffer which is constructed with ECL circuits.

The bases of the transistors Q₁₂ and Q₁₃ are biased with output voltages V₁ and V₂ of a writing circuit WA.

The writing circuit WA is constructed with the following circuit elements as shown in FIG. 8A.

The emitters of transistors Q₁, Q₂ and Q₃ are, in common, connected to a constant current source I₁. The current source I₁ is effected by with a transistor Q₆, the base of which is biased with a constant voltage V_(B4), and an emitter resistance R_(E1) thereof.

Each collector of the transistors Q₁ and Q₂ is connected to one end of resistors R₁ and R₂. The values of the resistors R₁ and R₂ are set to be equal, the other ends thereof are connected in common, and are connected to one end of a resistor R₃ the other end of which is connected to ground potential (0 volt). The anodes of diodes D₁ and D₂ are connected to the collectors of the transistors Q₁ and Q₂, respectively. The cathodes of the diodes D₁ and D₂ are commonly connected to the collector of a transistor Q₄.

The bases of the transistors Q₁ and Q₂ are coupled to receive an inverting and a non-inverting, writing data signals D_(IN) and D_(IN) formed by a data input buffer DIB that receives a writing data signal; in this case, the signal is supplied from a terminal D_(1N).

The collector of the transistor Q₃ is connected to the ground potential, and its base is biased with a control signal WE for reading and writing, which is generated by a control circuit in receiving control signals from terminals CS and WE. The signal WE is also inputted to the base of a transistor Q₄. The collector of a transistor Q₅, which transistor is differentially connected to the transistor Q₄, is connected to the ground potential and its base is biased with a reference voltage V_(R).

The commonly connected emitters of the transistors Q₄ and Q₅ are connected with a transistor Q₇ that receives a constant voltage V_(B5) and has an emitter coupled to resistance R_(E2) so as to provide a constant current source I₁₂.

A collector output of the transistor Q₁ is transmitted to the emitter-follower circuit comprising a transistor Q₈ and a constant current source, which is provided by a transistor Q₁₀ and an emitter resistance R_(E3) and connected to the emitter of the transistor Q₈. The output voltage of the emitter follower will be the reference voltage V₁, which is added to the base of a current switching transistor, for example the transistor Q₁₂ that can be connected to one of the data lines.

A collector output of the transistor Q₂, on the other hand, is transmitted to the emitter follower circuit comprising a transistor Q₉ and a consant current source, which is provided by a transistor Q₁₁ and an emitter resistance R_(E4) and connected to the emitter of the transistor Q₉. The output voltage of the emitter follower will be the reference voltage V₂, which is added to the base of a current switching transistor, for example the transistor Q₁₃ that can be connected to the other of the above mentioned data lines.

Signals WE, D_(IN) and D_(IN) and the reference voltage V_(R) of the writing circuit WA are being set as shown in FIG. 8B. According to the signals WE, D_(IN) and D_(IN), each of output voltages V₁ and V₂ of the writing circuit WA forms levels of three values.

FIG. 8C is a timing diagram illustrating an example of the operation of the above mentioned ECL circuit.

Except for the writing operation, the control signal WE has a high level H that is set higher than the high level H of the writing data signals D_(IN) and D_(IN), so the transistors Q₃ and Q₄ of the writing circuit WA are being turned on. Therefore, as constant current I₂ flows through diodes D₁ and D₂ through the resistors R₁ and R₂, dividing the current equally therethrough, and as the constant current flows through the resistor R₃, a collector voltage of the transistors Q₁ and Q₂ is obtained from the following expression (4). ##EQU1##

Now, from the above description, R₁ is equal to R₂, and the level of the voltage is shifted by the base-emitter voltage of the transistors Q₈ and Q₉, so a reference voltage Vrefc is generated as shown in FIG. 8C.

When the memory cell is not selected (X and Y are not selected), namely at time interval T₁, an electric potential of the word line W₀ or W_(n) is set less than the voltage Vrefc so that the column switch is off. Therefore, for example, the potential on the data lines D₀ and D₀ is approximately -2V_(BE) (V_(F) +V_(BE)) so that the transistors Q₁₂ and Q₁₃ are turned off, too. As for each memory cell, for example a represented one, not only a low level V_(C1) is held by a transistor Q₃₂ being turned on, but a high level V_(C2) is held by a turning off of a transistor Q₃₃.

When the memory cell is selected (X and Y are selected), namely during time interval T₂, a work line W₀ will be at a high level which is higher than the reference voltage Vrefc. The column switch transistors Q₁₉ to Q₂₁ are turned on, so a constant current I_(R) flows through one of the data lines D₀ and D₀.

As the constant current I_(R) also flows through a resistor R₇, the base potential of transistor Q₁₈ becomes less than the reference voltage Vrefc; thus, the transistor Q₁₈ is turned off. And with a potential increase of the word line W₀, the hold voltage V_(C1), V_(C2) of the memory cell rises, so the reference voltage Vrefc will have a value between them.

In this condition, a reading operation takes place for the memory cell selected. That is, in the above relationship of the electric potentials, the transistor Q₁₂ is off, and the transistor Q₁₃ is on. Therefore, the constant current I_(R) flowing through the transistor Q₁₃ is supplied to a resistor R₅ through the transistor Q₁₅, so the collector potential of the transistor Q₁₅ decreases and it is transmitted to the data output buffer DOB as a low level signal. However, the constant current I_(R) cannot flow through the transistor Q₁₂ that is turned off, so the output of this transistor is transmitted to the data output buffer as a high-level signal.

In this way, both of the selection and the reading of the memory cell are operated automatically.

Since the output condition of the data output operating buffer DOB is controlled by using a signal, coming from a control circuit CONT, the data contained in it are not always transmitted to the output terminal D_(OUT) as they are, only by the above mentioned selection of the memory cell.

When the memory cell is in the inverted writing phase during timing interval T₃, the control signal WE has a low level as shown in FIG. 8B. Therefore, the transistors Q₃ and Q₄ of the writing circuit WA are turned off, and the transistor Q₅ is on. Since the procedure is an inverted writing condition wherein a writing data signal D_(IN) has a high level H, the transistor Q₂ is turned on.

By turning on the transistor Q₂, a constant current I₁ flows into the resistors R₂ and R₃. In this way, the collector voltage V₂ ' of the transistor Q₂ is obtained from the following expression (5).

    V2'=-I1 (R2+R3)                                            (5)

And the collector voltage V₁ ' of the transistor Q₁ that is turned off, is obtained from the following expression (6).

    V1'=-I1 R3                                                 (6)

The voltage level V₂ ' is shifted by the base-emitter voltage of the transistor Q₉, and, as shown with the broken lines in FIG. 8C, forming a low level writing voltage V_(WL) that is less than the low level holding voltage V_(C1).

The level of the voltage V₁ ' is shifted, too, and forms a high level writing voltage V_(WE) that is higher than the high level holding voltage V_(C2).

The transistor Q₁₃ which receives the low level writing voltage V_(WL) (V₂) is turned off, because its base voltage V_(WL) is less than the base voltage V_(C1) of a transistor Q₃₃ that has a differential configuration connected to the data line D₀. Therefore, the transistor Q₁₃ causes the constant current I_(R) to flow into the transistor Q₃₃ thereby switching transistor Q₃₃ from off to on.

As for the transistor Q₁₂ that receives the high level writing voltage V_(WH) (V₁), its base voltage V_(WH) is higher than the base voltage V_(C2) of a transistor Q₃₂ that has a differential configuration connected to the data line D₀. Therefore, the transistor Q₁₂ is turned on so as to cut off an emitter current of the transistor Q₃₂ thereby switching the transistor Q₃₂ from on to off. Then, the holding voltages V_(C1) and V_(C2) are inverted where it is indicative of the inverted state condition.

In such a three-value system, the driving transistors Q₃₂ and Q₃₃ of the memory cell are directly switched on or off at the same time, and therefore a high speed writing operation can be executed.

In a half holding period T₄ for X selection and Y non-selection, the constant current I_(R) is cut off from flowing through the memory cell, and a bias voltage across the transistor Q₁₈ is applied to the data lines D₀ and D₀, and therefore the holding voltages V_(C1) and V_(C2) are shifted upwardly toward the high level.

In another half selection period T₅ for X non-selection and Y selection, the word line W₀ has a low level, so the holding voltages V_(C1) and V_(C2) are shifted to the low level, as is the same for the non-selected period T₁.

The above corresponds to a brief description of the operation of the typical bipolar static RAM. The inventors have investigated the results in conjunction with high speed operation and high integration of such random access memories, and, as a result of which, they have found the following problems associated with such SRAMs:

1. In bipolar static random access memories, an access speed etc. will determine a current level that should flow into a word line (for example W₀) or a line for the holding current (for example In), which are made of aluminum. However, when the current is increased in order to attain a high access speed, a potential drop associated with the word line becomes large owing to the writing resistance of the line, or the electro-migration is easy to occur.

As a result thereof, a wiring width of the word line and so on cannot be too small and therefore the aluminum wiring width is a barrier that makes it difficult to decrease the area or dimensions of memory cells. That is, there is a tendency for increasing the width of the aluminum wirings associated with such lines.

2. When the capacity of memory cells increases, a wiring length of the word line etc. becomes larger and larger; therefore, there results in a corresponding increase in the amounts of a potential drop of the word line. This leads to the problems that the operation margin of the memory cell becomes low, or the reading speed differs between the first memory cell (for example MC1) connected to the word line (for example W₀) and the last cell.

The present invention intends to solve the above problems, and nextly the embodiments of the invention will be described according to the attached drawings.

EMBODIMENTS

Embodiment 1

FIG. 1 is an equivalent circuit of a static RAM comprising emitter coupled memory cells according to the first embodiment of the invention. A memory cell of the figure M-Cell 1 consists of Schottky barrier diodes d1, d2; capacitors C1, C2, each of which is connected in parallel to one of the Schottky barrier diodes d1, d2; multi-emitter transistors q1, q2, the collectors of which are connected in series with the Schottky barrier diodes d1, d2 and the capacitors C1, C2; and load resistances r1, r2, each of which is connected in parallel with the Schottky barrier diodes d1, d2 and connected in series with each base of the multi-emitter transistors q1, q2. That is, information stored in the memory cell M-Cell is held by using the flip-flop circuit comprising the above mentioned elements, q1, q2, r1, r2, d1, d2, c1 and c2. The information of the memory cell M-Cell 1 is being held with a current I_(ST) that flows through a holding current line ST. The memory cell M-Cell 1 is connected with the signal lines (for example word line W100, data line D,D etc.). The word line of the memory cells in each row such as memory cell M-Cell 1, for example, has a double construction (for example, W100 and W200 are connected in parallel). Such memory cells as the M-Cell 1, M-Cell 2, etc. are arranged along the word lines (W100, W200, etc.), constructing a memory line for a row of memory cells; and a plurality of such memory lines are arranged in the direction of data lines (D, D) forming a plurality of columns of memory cells, each column associated with a pair of complementary data lines (D, D) thereby constructing a memory array of matrix type.

When the memory cell M-Cell 1 is selected, the word line W100 connected to a transistor QA0 is selected by an external signal that is entered into input terminals A0, - - - , An of a row address decoder X-DCR; and the data lines D, D are selected by a column address decoder (not shown in the figure).

A static RAM comprising the above mentioned emitter-coupled memory cells has double signal lines (word lines) associated with memory line or row, so the electromigration cannot occur even if a large reading current (for example 10 mA), when the information is read out, flows through the signal line in order to increase an access speed of the RAM. Furthermore, a potential drop across the ends of signal lines due to the wiring resistance of signal lines (word lines) can be half or less compared with the wiring resistance in the case of a single signal line (word line).

Embodiment 2

FIG. 2 shows a static RAM memory cell comprising an emitter-coupled memory cell and a layout of the signal lines (word line, data line, etc.), where, in the same way as the case of FIG. 1, Schottky barrier diodes and capacitors are connected in parallel with load resistances).

Such memory cells as those having a layout shown in FIG. 2 are densely arranged in such a way that they come face to face with the adjacent, upper and lower memory cells, then a memory line is constructed along the word lines W100 and W200. A plurality of such memory lines, when they are arranged in the horizontal direction, form a memory array of matrix type.

In FIG. 2, the alphanumerics SBD1 and SBD2 show regions formed by the Schottky barrier diodes d1 and d2, adjacent to which there are provided regions formed by resistors r2 and r1, respectively. In this embodiment, the first aluminum layer Al₁₁ (2400) is formed on the diode-formed region SBD1 (SBD2), and is extended on a resistor-formed region RE2 (RE1); and then the aluminum layer is connected to a P-diffusion layer 3400 (refer to FIG. 5) of the semiconductor surface at contact holes CONT1 and CONT2. This makes it possible to contact an anode terminal of the Schottky barrier diode d1 (d2) to a terminal of the resistor r2 (r1). The aluminum layer Al₁₁ (2400) can be not only of Al-Si(2%) alloy but of Al-Si(2%)-Cu(3%) alloy.

Regions Q100 and Q200 forming transistors q1 and q2 are provided in approximately rectangular shape continuing to the diode-forming regions SBD1 and SBD2 and to the resistor-forming regions RE2 and RE1. On adjacent portions of the transistor-forming regions Q100 and Q200 to the resistor-forming regions RE2 and RE1, emitter regions E11 and E21 are formed, on which are provided polysilicon layers PS11 and PS21, respectively.

On the other ends of the transistor-forming regions Q100 and Q200, collector drawing regions CN1 and CN2 are arranged, respectively. And adjacent to the collector drawing regions CN1 and CN2, base-contact holes B2 and B1 are arranged, respectively, in the opposite-side transistor-forming regions Q200 and Q100. The collector drawing regions CN1 and CN2 although not particularly limited thereto, are connected through the polysilicon layers PS12 and PS22 to the base drawing electrodes Al₂₂ and Al₁₂ that are formed on the base contact holes B2 and B1. In this way, the transistors q1 and q2 will have a cross coupling between their bases and collectors. The base drawing electrodes Al₁₂ and Al₂₂ are formed by the first aluminum layer.

A second emitter region E12 (E22) is provided between the collector drawing region CN1 (CN2) and the base contact hole B1 (B2). On the emitter regions E12 and E22, polysilicon layers PS13 and PS23 are formed, respectively. The polysilicon layers PS13 and PS23 are connected with each other by the first aluminum layer Al₁₃.

A capacitor-forming region HiC1 (HiC2) is provided on the opposite side of the resistor-forming region RE2 (RE1), accross the diode-forming region SBD1 (SBD2) and adjacent to the emitter region E11 (E21). An electrode layer 1800 of the capacitor that is so formed as to cover the capacitor-forming region HiC1 (HiC2) is extended toward the outside of the cell, namely, toward the side of the diode-forming region SBD1 (SBD2). Then, the aluminum layers Al₁₁ and Al₂₁ (2400) are formed to cover the resistor-forming regions RE2, RE1 and the diode-forming regions SBD1, SBD2, and extended to the sides of the capacitor-forming regions HiC1, HiC2 so as to fall on the electrode layer 1800; the aluminum layer 2400 and the electrode layer are connected with each other through an opening 1900a.

On the capacitor-forming region HiC1 (HiC2) and the adjacent emitter region E11 (E21), a digit wire D (D) of the first aluminum layer is laid and connected to the polysilicon layer PS11 (PS21).

Moreover, on the memory cell that is formed, as according to the above mentioned layout, there are arranged the word line W100 formed of the second aluminum layer at right angles with the digit lines D and D, and a holding current line where a current is flown to keep the information of the memory cell at any time (it is called stand-by current, too).

The word line W100 is connected to the aluminum layer Al₁₁ (Al₂₁) used as an anode terminal of the Schottky barrier diode d1 (d2) at the position of a through hole TH1. The aluminum layer Al₂₁ is formed in one body with the aluminum layer Al₁₁ of the Schottky barrier diode d1 accommodated in the adjacent memory cell, and then connected to the word line W100.

The holding current line ST is, on the contrary, connected to an aluminum layer Al₁₃ for connecting the second emitters E12 and E22 in common at a through hole TH2, and the stand-by current flows through one of the emitters E12 and E22. Each wiring width of the word line W100 and the holding current line ST is for example, 7 μm or so.

In this embodiment, a reinforced word line W200 is laid on the word line W100, forming the third aluminum layer. The reinforced word line W200 is formed wider, for example 14 μm, than the word line W100 of the second aluminum layer, and the word lines W100 and W200 are connected with each other at the effective hole TH3. Therefore, a wiring resistance and corresponding potential drop will be decreased compared with a word line that is formed only with the second aluminum layer. And by adding the word line W200 that is formed with the third aluminum layer, the width of the second aluminum layer W100 can be made smaller than in the case without having the third layer. Therefore, an area occupied by the memory cell can be of a minimum required value that is determined by the manufacturing dimensions and characteristics of elements.

In this way, the word line has a double-layer construction of aluminum, and the layers of each memory cell are connected with each other at one position by using the through hole TH3; therefore, even if one of the wirings breaks along its path, the operation of the associated memory cells can still be maintained by the remaining wiring word line. The second and third aluminum wirings can be formed with layers of Al-Si(2%) alloy or Al-Cu(3%)-Si(2%) alloy.

The periphery of such a memory cell and boundaries of the symmetrical elements have a deep trench isolation region T-ISO (or U-groove isolation region) formed in such a way as to pass through the N⁺ embedding layer, so an isolation is made between the elements. And a shallow isolation region 900' (shown by hatching in FIG. 2) is formed on the boundary between the diode-forming region SBD1 (SBD2) and the capacitor-forming region HiC1 (HiC2). Referring to FIG. 1, the elements encircled with dotted, chained lines F1 and F2 are separated from one another by using the trench isolation region T-ISO.

FIG. 3 shows a cross section cut along the line II--II of FIG. 2, that is, an example of the cross sectional construction of the Schottky barrier diode and capacitor, which are connected in parallel with the load resistor.

As shown in FIG. 3, such a semiconductor substrate 100 as made of P-type single-crystal silicon has an N⁺ embedding layer 200 of high density, which is formed on the substrate with its periphery encircled by such a separating region 900 as the trench isolation region. An N-type semiconductor region 1100 of low density and an N⁺ -type semiconductor region 1200 of high density are formed, respectively, on the N⁺ embedding layer 200; and between the N-type region 1100 and the N⁺ -type region 1200, a shallow trench isolation region 900' is formed, having a depth to touch the N⁺ embedding layer 200 so that both of the semiconductor regions 1100 and 1200 are separated.

An opening 400a is formed through a film of silicon oxide 400 that is laid on the surface of the semiconductor substrate 100, and an opening 1500 is formed through isolation films 1300 and 1400 that are laid on the film 400; in this case, the openings are so formed as to correspond, respectively, to the N⁺ -type semiconductor region 1200 of high density. From the inside of the opening 1500 to its periphery is formed an isolation film 1700 of transition metal oxide, for example tantalum oxide (Ta₂ O₅), having a high dielectric constant. On the isolation film 1700, an electrode layer 1800 is formed, comprising a metal of high melting point such as tungsten (W) or molybdenum (Mo), or comprising their silicon compounds (WSi, MoSi) and so on; thus, between the electrode layer 1800 and the N⁺ -type semiconductor region 1200, a capacitor having a large dielectric capacity per unit area is formed.

In the meantime, a contact hole 2000 is formed through the isolation films 1300 and 1400 that are laid on the surface of the N-type semiconductor region 1100 of low density, which is prepared on the N⁺ embedding layer 200. Then, on the surface of the semiconductor region 1100 that is formed inside the contact hole 2000, an electrode layer 2100 and an aluminum layer 2400 are formed by three-series metals, for example PtAl₂ Si, that have a low barrier height φB against silicon. The electrode layer 2100 can be made by reacting aluminum and platinum silicide: for example, a platinum silicide (PtSi) layer is formed at first on the surface of the semiconductor region 1100, secondly, the aluminum layer 2400 is vaporized, and then a sinterring (heat treatment about 500° C.) is done.

As described above, in this embodiment, an isolation film 1900 such as a PSG (phosphorus-silicate-glass) film is formed on the electrode layer 1800 of the portion of the capacitor (or on the isolation film 1400 outside the electrode layer 1800), and the opening 2000 is prepared through the isolation film 1900 corresponding to the electrode layer 2100. The aluminum layer 2400 for connection, is formed on the PSG film 1900; thus, the electrode layer 2100 of the Schottky barrier diode for the capacitor is connected at the opening 2000.

The second aluminum layer 2700 is prepared to form the word line W100 on the aluminum layer through a layer-to-layer isolation film 2600; moreover, the third aluminum layer 2900 is prepared to form the reinforced word line W200 on the aluminum layer 2700 through a layer-to-layer isolation film 2800.

In this embodiment, a capacitor having a different electrode construction and a Schottky barrier diode are formed on the N⁺ embedding layer 200 that is surrounded with the trench isolation region 900. Therefore, the capacitor and the Schottky barrier diode need not be formed separately so that the separation region can be used for another element to be integrated in high density.

Furthermore, the N⁺ -type semiconductor region 1200 should be formed in such a way that, after being doped with an N-type impurity (phosphorus or arsenic), it is diffused by heat to a depth reaching N⁺ embedding layer 200. In this case, if there is no trench isolation region 900' between the semiconductor region 1200 where a capacitor is formed and the semiconductor region 1100 where a diode is, formed, impurities are diffused along the horizontal direction, too. Therefore, an area of the semiconductor region on the N⁺ embedding layer 200 should be large enough to prevent the contact of the diode electrode layer and the N⁺ -type semiconductor region 1200 of the capacitor. And then, a mating margin should be kept between a penetrating mask for N-type impurities and the mask that forms an opening of the N-type semiconductor region 1100. In this way, it requires a large area occupied by the forming regions for capacitors and diodes.

As for the embodiment of the invention, on the contrary, the N-type semiconductor region 1100 and the N⁺ -type semiconductor region 1200 are now separated by a shallow trench isolation region 900' so that there is no diffusion of impurities along the horizontal direction, and therefore not only the area of the N⁺ semiconductor region 1200 can be decreased, but the mating margin of the mask need not be considered for penetrating the N-type impurities. In this way, the area of the N⁺ -type embedding layer 200 and the upper semiconductor region, that is, the area occupied by the diode and the capacitor is greatly decreased; this makes a high integration possible.

FIG. 4 shows a cross sectional, diagram cut along III--III of FIG. 2.

In the figure, the electrode layer 1800 of the capacitor is extended to the outside of N⁺ -type semiconductor region 1200 (capacitor forming region HiC); the PSG film 1900 is formed on the electrode layer 1800; and the opening 1900a is formed corresponding to the extended part of the electrode, connecting to the aluminum layer 2400 that is extended from the diode. Therefore, if the metal of high melting point that constructs the electrode layer 1800 reacts with the aluminum layer 2400 which is vaporized on it, and is alloyed so that the aluminum layer 2400 passes through the electrode layer 1800, the reaction could not reach the surface of the N⁺ -type semiconductor region 1200, because the connection is made outside the capacitor. The upper part of the electrode layer 1800 that is laid on the surface of the N⁺ -type semiconductor region, furthermore, is covered with the PSG film 1900. Therefore, the heat resistance of the capacitor is largely improved compared with that of the electrode layer 1800 and the aluminum layer 2400 which are to be connected on the semiconductor region 1200.

In this embodiment, the aluminum wiring layer forming a digit line or a data line D (D), is formed and over the PSG film 1900 on the N⁺ -type semiconductor region 1200 which will form a capacitor. Thus, if the electrode layer 1800 of the capacitor is extended outside so as to effect contact with the aluminum layer 2400 as mentioned above, the area of the cell can never be increased, rather it is decreased.

In other words, the conventional emitter-coupled memory cell having a Schottky barrier diode, in general, has a comparatively large non-formed region under the digit lines D, D, where any element is not formed yet. However, according to the embodiment of the present invention, a capacitor is largely formed under the digit line, so the connection with the aluminum layer is done outside. Therefore, an extra non-formed region can scarcely be generated, thus the cell area is decreased to make the high integration possible.

FIG. 5 shows a cross section cut along the line IV--IV of FIG. 2. In the figure, the aluminum wirings of the second and third layers are omitted, and the films inserted between the layers are not shown except for the first aluminum layer.

In FIG. 5, numeral 3100 shows represents a P⁺ -type semiconductor region that forms the base of the transistor q1 (or q2) of the memory cell shown in FIG. 1, alphanumerics 3200a and 3200b show represent N⁺ -type semiconductor regions forming the emitters of the transistor q1 (q2), and a numeral 3300 is an N⁺ -type semiconductor region forming the collector lead-out region of the transistor q1 (q2).

In this embodiment, although there is no particular restriction, each h_(FE) (direct current amplifying coefficient) has the optimum value by changing the base thickness just under the emitter regions 3200a and 3200b.

The N-type semiconductor region 1100 that forms a Schottky barrier diode d1 (or d2) is laid on the N⁺ embedding layer 200 that forms the collector region of the transistor q1 (q2); and between the N-type semiconductor region 1100 and the base region 3100, a shallow P⁻ -type semiconductor region 3400 is formed to be a load resistance r2 (or r1). A trench isolation region 900 is provided between the semiconductor regions 1100 and 3400. It is clear from FIG. 2 that the trench isolation region 900 changes from a deep one to a shallow one (shown by the hatching) on its way. This changes the cross sectional area of the N⁺ embedding layer 200 that connects the semiconductor region 1100 and the collector region of the transistor q1, and adjusts a value of a resistor connected in parallel with the diode d1.

Moreover, in this embodiment, a shallow trench isolation region 900'" is formed, too, between the base region 3100 and the collector drawing tip 3300.

An aluminum layer 2400 is formed on the isolation films 1300, 1400 and 1900, all of which cover the surface of not only the N-type semiconductor region 1100 forming the Schottky barrier diode d1 (d2) but also the P⁻ -type semiconductor region 3400 forming the load resistance; and the aluminum layer contacts with the electrode layer 2100 of the Schottky barrier diode at the position of contact hole 2000. A part of the aluminum layer 2400 is extended so as to be in contact with the P⁻ -type semiconductor region 3400 at the position not shown in the figure, the anode terminal of the diode d1 (d2) being connected with one terminal of the resistor r2 (r1). Moreover, an aluminum electrode 2400b used for drawing the base, is formed inside of a contact hole 2000b that is provided through the isolation films 1300 and 1400 on the surface of the base region 3100.

Inside the contact holes 2000c, 2000d and 2000e that are formed on the isolation films 1300 electrodes 3600a, 3600b and 3600c are formed and 1400 laid on the substrate, polysilicon corresponding to the emitter electrodes 3200a, 3200b and the collector lead-out region 3300. Aluminum electrodes 2400c, 2400d and 2400e are formed on the polysilicon electrodes 3600a, 3600b and 3600c through an isolation film 1900.

In FIG. 4 and FIG. 5 that show the cross sections cut along the line III--III and the line IV--IV of FIG. 2, the isolation films 2600 and 2800 are not shown if they are formed above the first aluminum layer.

Embodiment 3

FIG. 6 shows the third embodiment of the invention where the layout and construction of the signal line (word line) are changed from the static RAM of FIG. 2.

According to this embodiment, a pair of the digit lines D and D are formed by the first aluminum layer, and the word line W and the hold current line ST are, respectively, formed by the second and third aluminum layers. Then, word lines W100 and W200 made of the second and third aluminum layers, are connected with each other at the through hole TH3 that is shown in FIG. 2; and hold current lines ST1 and ST2, which are of the second and third aluminum layers, are connected with each other at the through hole TH4. In this embodiment, a distance of each wiring is made to the minimum which is determined by the lithography, and the wirings of the second and third layers are so formed as to have approximately the same dimensions: this is intended to decrease the wiring resistance, namely to increase the cross section within the range of width that the memory cell has.

Embodiment 4

FIG. 7 shows the fourth embodiment of the invention, in which the digit lines D and D are formed with the first and second aluminum layers, and the word line W and the hold current line ST are formed with the third and fourth aluminum layers. The digit lines D1, D2 (D1, D2) of the first and second layers are connected with each other by using a through hole TH5. The alphanumerics TH3' and TH4 show through holes to connect the upper and lower word lines and the hold current line ST.

In this embodiment, it is possible to high speed operation by decreasing the wiring resistance and increasing a current flowing through a digit line.

The digit line and the hold current line can be formed with a layer which stands at any number of order, so this is not restricted to the embodiment. And the construction and layout of memory cells are not restricted to the embodiment of FIG. 2. Moreover, the number of layers is not restricted to two: three or more layers are possible.

So far are described the embodiments of the inventive bipolar static RAM, where, among the signal lines that are arranged on a cell of the memory array, at least the word lines are constructed as pairs of conducting lines, so the wiring width can be narrowed without decreasing a cross section of the wiring; therefore, an effect that the circuit-occupied area is not restricted by the width of aluminum wirings, produces the results that the area occupied by the memory array or the memory cell can be decreased and that a random access memory of the smaller chip size can be produced.

Since at least the word lines are constructed in pairs of conducting lines among the signal lines arranged on the cell of the memory array, there results a decrease in the wiring resistance; this leads to a decrease potential drop of the wiring and in the prevention in electromigration.

Although this invention has been described specifically in reference to the exemplified embodiments, it will be understood that various modifications may occur within the scope of this invention which is defined by the appended claims. In the embodiments, for example, the explanation is done for word lines, hold current lines and digit lines that are formed on a high-density memory array. However, this invention can also be applied to signal lines that are arranged, except for memory arrays, to word line driving circuits, sense-amplifier circuits and so on. Moreover, a wiring material is not restricted to aluminum, but Al-Si (2%) alloy or Al-Cu (3%) -Si (2%) alloy can be used for wirings.

This invention has mainly been described about the application to the signal lines of a bipolar, static random access memory; this is an application field of the inventive background. However, the invention is not restricted to this application; it can be used not only for power supply lines, but for wirings in general, for example in semiconductor integrated circuits, etc.

The following is a brief description of the effects that are obtained from the typical explanation of this invention.

That is, the chip size can be decreased in large-scale integrated circuits; a potential drop due to the wiring becomes small; and the electromigration will not occur. 

What is claimed is:
 1. A semiconductor memory device comprising:a semiconductor body having a main surface; a plurality of memory cells formed on said main surface, each memory cell having a pair of bipolar transistors; a memory cell array including a word line and a plurality of pairs of complementary digit lines, said word and complementary digit lines being coupled to selection circuits and being coupled to said memory cells so that each memory cell is coupled to said word line and to a pair of complementary digit lines, said word line including first and second lines each made of a separate conductive layer material extended over a region where said memory cells are formed; and a current line coupled to a current source circuit on said main surface and being coupled to each memory cell, said current line being made of a conductive layer material extended along a direction corresponding to that of said word line and over said region where said memory cells are formed, wherein said second line is stacked over said first line, and wherein said first and second lines are electrically connected to each other at predetermined intervals along the lengths of said first and second lines through respective openings formed in an insulating film which is interposed between the separate conductive layer materials which form said first and second lines.
 2. A semiconductor memory device according to claim 1, wherein the second line of said word line has a width which is greater than that of said first line.
 3. A semiconductor memory device according to claim 2, wherein the first line of said word line and said current line are made of the same conductive layer material, and wherein the second line of said word line extends over said current line so that the second line of said word line is stacked over said current line.
 4. A semiconductor memory device according to claim 3, wherein said insulating film interposed between the separate conductive layer materials which form said first and second lines further extends over said current line, and wherein said second line and said current line are electrically isolated from each other by said insulating film extended over said current line.
 5. A semiconductor memory device according to claim 1, wherein said pair of bipolar transistors of each memory cell are composed of first and second bipolar transistors, wherein a collector of said first bipolar transistor is coupled to a base of said second bipolar transistor and a collector of said second bipolar transistor is coupled to a base of said first bipolar transistor, and wherein each of said first and second bipolar transistors has at least a first emitter, said first emitters thereof are coupled to a corresponding one of a pair of complementary digit lines.
 6. A semiconductor memory device according to claim 5, wherein each one of said first and second bipolar transistors further comprises a second emitter, and wherein said second emitters of said first and second bipolar transistors are coupled to each other and to said current line coupled to said current source circuit.
 7. A semiconductor memory device according to claim 6, wherein each of said memory cells further comprises a first load circuit coupling the collector of said first bipolar transistor to said word line and a second load circuit coupling the collector of said second bipolar transistor to said word line.
 8. A semiconductor memory device according to claim 7, wherein said first and second load circuits of each of said memory cells comprise first and second parallel connections, respectively, each one thereof including a parallel arrangement of a resistance element, a Schottky barrier diode and a capacitor.
 9. A semiconductor memory device comprising:a semiconductor body having a main surface; a plurality of memory cells formed on said main surface, each memory cell having a pair of bipolar transistors; a memory cell array including a plurality of word lines and a plurality of pairs of complementary digit lines, said word and complementary digit lines being coupled to selection circuits and being coupled to said memory cells so that each memory cell is correspondingly coupled to a word line and to a pair of complementary digit lines, each of said word lines being extended in a predetermined direction and each pair of complementary digit lines being extended in a substantially orthogonal direction to said predetermined direction above said main surface, wherein each one of said word lines includes a first wiring layer and a second wiring layer stacked over said first wiring layer, and wherein each word line extends over a region where said memory cells which are correspondingly coupled therewith are formed; a plurality of current lines, each one thereof being coupled to a current source circuit on said main surface and being coupled to memory cells correspondingly with a respective word line, wherein each one of said current lines includes a third wiring layer which extends along a direction common to the direction of the corresponding word line and over said region where memory cells correspondingly coupled therewith are formed; and an insulating film interposed between said first and second wiring layers of each one of said plurality of word lines, wherein said first and second wiring layers of each one of said plurality of word lines are electrically connected to each other at predetermined intervals along said predetermined direction through respective openings formed in said insulating film.
 10. A semiconductor memory device according to claim 9, wherein the second line of each one of said word lines has a width which is greater than that of said first line.
 11. A semiconductor memory device according to claim 10, wherein the first line of each one of said plurality of word lines and said plurality of current lines are made of the same conductive layer material, and wherein the second line of each one of said plurality of word lines respectively extends over a corresponding one of said plurality of current lines so that the second line of each one of said plurality of word lines is stacked over a corresponding one of said plurality of current lines.
 12. A semiconductor memory device according to claim 11, wherein with respect to each word line and corresponding current line said insulating film interposed between the separate conductive layer materials which form said first and second lines further extends over said current line, and wherein the second line of each one of said plurality of word lines and each corresponding one of said plurality of current lines are electrically isolated from each other by said insulating film extended over said current line.
 13. A semiconductor memory device according to claim 9, wherein said pair of said bipolar transistors of each memory cell are composed of first and second bipolar transistors, wherein a collector of said first bipolar transistor is coupled to a base of said second bipolar transistor and a collector of said second bipolar transistor is coupled to a base of said first bipolar transistor, and wherein each of said first and second bipolar transistors has at least a first emitter, said first emitters thereof are coupled to a corresponding one of a pair of complementary digit lines.
 14. A semiconductor memory device according to claim 13, wherein each one of said first and second bipolar transistors further comprises a second emitter, and wherein said second emitters of said first and second bipolar transistors are coupled to each other and to one of said plurality of current lines coupled to said current source circuit.
 15. A semiconductor memory device according to claim 14, wherein each of said memory cells further comprises a first load circuit coupling the collector of said first bipolar transistor to a corresponding one of said plurality of word lines and a second load circuit coupling the collector of said second bipolar transistor to said corresponding word line.
 16. A semiconductor memory device according to claim 15, wherein said first and second load circuits of each of said memory cells comprise first and second parallel connections, respectively, each one thereof including a parallel arrangement of a resistance element, a Schottky barrier diode and a capacitor. 